DE102013111936A1 - Doherty amplifier circuit with phased load modulation - Google Patents

Abstract

A balanced Doherty amplifier (100) has a main amplifier (102) and a peak amplifier (104) of the same size as the main amplifier (102). The balanced Doherty amplifier is configured to operate at peak output power when the main amplifier (102) and peak amplifier (104) are both saturated and to operate at output back-off (OBO) when the main amplifier (102) is in Is saturated and the peak amplifier (104) is not in saturation. Phase shifting circuits (118) are configured to shift the phase at an output of the peak amplifier (104) at OBO so that a load impedance perceived by the main amplifier (102) and the efficiency of the balanced Doherty amplifier both at OBO as a function of the phase shift at the output of the peak amplifier (104).

Description

TECHNICAL AREA

The present application relates to Doherty amplifiers, in particular Doherty amplifiers, having efficient operation over a wide output back-off (OBO) range. (Output back-off, OBO = output power withdrawal)

BACKGROUND

RF (Radio Frequency) powering architectures within the telecommunications area focus on achieving high DC-to-RF efficiency with significant power recovery from the Psat value (the average output power when the amplifier is driven deep into saturation). The reason for this is the high peak-to-average ratio (PAR) of the transmitted digital signals, such as W-CDMA (Wideband Code Division Multiple Access), LTE (Long Term Evolution) and WiMAX (Worldwide Interoperability for Microwave Access). The most popular power amplifier architecture currently in use is the Doherty amplifier. The Doherty amplifier uses a class AB main amplifier and a class C peak amplifier, and efficiency is improved by load modulation of the main amplifier from the peak amplifier.

When high efficiency is needed with a high output back-off (OBO), a highly asymmetric ratio between the size of the main and the peak amplifiers is usually required. However, such an asymmetry requirement limits the maximum RF output power that can be achieved from such a design. A 3-way Doherty amplifier can also be used to operate at more than 6 dB away from the peak output power; H. at more than 6 dB OBO. However, 3-way Doherty amplifiers are complicated, have the problems of a long design process and lacking consistency of performance, and require a larger physical layout. None of the above-mentioned approaches allows dynamic load modulation. An architecture called "Envelope Tracking" or "Drain Modulation" can also be used to achieve high efficiency at more than 6 dB OBO, but this approach requires a very substantial system redesign and additional complexity.

SUMMARY

Embodiments described herein will do without differently sized transistors in Doherty amplifier circuit designs, and will allow for greater efficiency when spaced at a distance of 6 dB or more from the peak output power, i. H. at 6 dB OBO or more, work. The symmetrical Doherty amplifier circuit described herein has a main amplifier and a peak amplifier of the same size. By dynamically controlling the Voltage Standing Wave Ratio (VSWR) sensed by the main amplifier, the maximum efficiency operating point of the symmetrical Doherty amplifier at OBO can be dynamically swept over the output power range of interest. The VSWR is a measure of the load that the main amplifier perceives at a particular output power level relative to the load perceived by the main amplifier at the Doherty peak power level. The VSWR can be controlled by shifting the phase at the output of the peak amplifier at OBO. For example, with high efficiency, the Doherty balanced amplifier circuit can be operated anywhere between 6 dB OBO and 12 dB OBO or even higher OBO by adjusting the VSWR sensed by the main amplifier.

According to one embodiment of a Doherty amplifier circuit, the circuit comprises a symmetrical Doherty amplifier having a main amplifier and a peak amplifier of the same size as the main amplifier. The symmetrical Doherty amplifier is configured to operate at peak output power when the main amplifier and the peak amplifier are each in saturation, and to operate at output back-off (OBO) when the main amplifier is in saturation and the peak amplifier is not in saturation , The Doherty amplifier circuit further includes phase shifter circuits configured to shift the phase at the output of the peak amplifier at OBO so that a load impedance sensed by the main amplifier and the efficiency of the Doherty symmetric amplifier both at OBO as a function of the phase shift on the Increase peak amplifier output.

According to another embodiment, the phase shifter circuits optionally include a first phase shifter coupled to an input of the main amplifier and a second phase shifter coupled to the output of the peak amplifier, and wherein the first and second phase shifters are configured to have the same phase shift perform.

According to another embodiment, the Doherty amplifier circuit optionally further includes a Doherty combiner for doing so is configured to couple the main and the peak amplifiers to a load, the phase shifter circuits further comprising a third phase shifter integrated with the Doherty combiner, and wherein the first phase shifter and the third phase shifter provide a combined phase shift approximately is equal to a phase shift provided by the second phase shifter.

According to another embodiment, the phase shifter circuits are optionally configured to shift the phase at the output of the peak amplifier by 10 to 60 degrees at OBO.

According to another embodiment, the phase shifter circuits are optionally configured to shift the phase at the output of the peaking amplifier at OBO over a range of degrees sufficient to achieve a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO at an operating point between at least 6 dB OBO and 12 dB OBO to move.

According to another embodiment, the phase shifter circuits are optionally configured to shift the phase at the output of the peaking amplifier at OBO by extending a phase line connected to the output of the peaking amplifier and extending a phase line connected to an input of the main amplifier.

According to another embodiment, the phase shifter circuits are optionally configured to extend the phase lines by 10 to 60 degrees at OBO.

According to an embodiment of a method of operating a Doherty amplifier circuit having a main amplifier and a peak amplifier of the same size as the main amplifier, the method comprises: operating the balanced Doherty amplifier at peak output power when the main amplifier and the peak amplifier are each in the saturation state , and output back-off (OBO) when the main amplifier is saturated and the peak amplifier is not saturated; and shifting the phase at the output of the peak amplifier at OBO such that a load impedance sensed by the main amplifier and the efficiency of the symmetrical Doherty amplifier both increase at OBO as a function of the phase shift at the peak amplifier output.

According to a further embodiment, shifting the phase at the output of the peak amplifier at OBO comprises applying the same phase shift to the output of the peak amplifier and to an input of the main amplifier.

According to another embodiment, the method further comprises applying the same phase shift to a phase line of a Doherty combiner coupling the main and the peak amplifiers to a load.

According to another embodiment, the phase at the output of the peak amplifier is shifted by 10 to 60 degrees at OBO.

According to another embodiment, the phase at the output of the peak amplifier at OBO may be shifted over a range of degrees sufficient to move a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO to an operating point between at least 6 dB OBO and 12 dB OBO.

In another embodiment, shifting the phase at the output of the peaking amplifier at OBO comprises: extending a phase line connected to the output of the peaking amplifier; and extending a phase line connected to an input of the main amplifier.

According to another embodiment, the phase lines are extended by 10 to 60 degrees at OBO.

According to another embodiment of a Doherty amplifier circuit, the circuit comprises: a symmetrical Doherty amplifier having a first amplifier of a first size and a second amplifier of a second size equal to the first size. The symmetrical Doherty amplifier is configured to operate at peak output power when the first amplifier and the second amplifier are each in saturation, and to operate at output back-off (OBO) when the first amplifier is in saturation and the second amplifier is not in the saturation state. The Doherty amplifier circuit further includes circuitry configured to dynamically control a voltage standing wave ratio (VSWR) sensed by the first amplifier to accommodate a maximum efficiency operating point of the symmetrical Doherty amplifier OBO to an operating point between at least 6 dB OBO and 12 dB OBO by changing the VSWR, which is detected by the first amplifier can move.

According to another embodiment, the circuits optionally include a phase shifter configured to phase up the phase Output of the second amplifier at OBO to shift so that the VSWR, which is detected by the first amplifier increases at OBO.

According to another embodiment, the phase shifter is configured to shift the phase at the output of the second amplifier at 10 to 60 degrees at OBO.

According to another embodiment, the phase shifter is configured to shift the phase at the output of the second amplifier at OBO by extending a phase line connected to the output of the second amplifier.

According to another embodiment, the phase shifter is configured to extend the phase line at 10 to 60 degrees in OBO.

According to another embodiment for operating a Doherty amplifier circuit having a first amplifier of a first magnitude and a second amplifier of a second size equal to the first magnitude, the method comprises: operating the symmetrical Doherty amplifier at peak output power when the first amplifier and the second amplifier are each in the saturation state, and output back-off (OBO) when the first amplifier is in the saturation state and the second amplifier is not in the saturation state; and dynamically controlling a Voltage Standing Wave Ratio (VSWR) sensed by the first amplifier, such that a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO is at an operating point between at least 6 dB OBO and 12 dB OBO Changing the VSWR that is perceived by the first amplifier can move.

In another embodiment, dynamically controlling the VSWR sensed by the first amplifier includes shifting the phase at an output of the second amplifier at OBO such that the VSWR sensed by the first amplifier increases at OBO.

According to another embodiment, the phase at the output of the second amplifier is shifted by 10 to 60 degrees at OBO.

According to another embodiment, shifting the phase at the output of the second amplifier at OBO comprises extending a phase line connected to the output of the second amplifier.

According to another embodiment, the phase line is extended by 10 to 60 degrees at OBO.

According to yet another embodiment of a Doherty amplifier circuit, the circuit comprises a Doherty amplifier and phase shifter circuits. The Doherty amplifier comprises a main amplifier and a peak amplifier and is configured to operate at peak output power when the main amplifier and the peak amplifier are each in saturation, and to operate at output back-off (OBO) when the main amplifier is in saturation and the peak amplifier is not in the saturation state. The phase shifter circuits are configured to shift the phase at an output of the peak amplifier at OBO so that a load impedance sensed by the main amplifier and the efficiency of the Doherty amplifier both increase at OBO as a function of the phase shift at the peak amplifier output.

Those skilled in the art will recognize further features and advantages upon reading the following detailed description and upon reviewing the accompanying drawings.

BRIEF DESCRIPTION OF THE FIGURES

The elements of the drawings are not necessarily to scale relative to each other. Like reference numerals designate corresponding similar parts. The features of the various illustrated embodiments may be combined unless they are mutually exclusive. Embodiments are shown in the drawings and will be detailed in the following description.

1 FIG. 12 illustrates a schematic of a Doherty balanced amplifier circuit having a phase shifted peak amplifier output at OBO according to one embodiment. FIG.

2 Figure 13 is a graph showing the main amplifier efficiency as a function of the OBO for various phase shifts at the peak amplifier output.

3 Figure 13 is a graph showing the main amplifier load modulation as a function of the phase shift at the peak amplifier output.

4 Fig. 10 is a diagram showing the main amplifier efficiency as a function of the OBO.

5 illustrates a circuit diagram of a symmetrical Doherty amplifier circuit with a phase shifted peak amplifier output according to another embodiment.

6 FIG. 12 illustrates a circuit diagram of a phase shifter included in the symmetrical Doherty amplifier circuit according to one embodiment. FIG.

7 FIG. 12 illustrates a circuit diagram of a phase shifter included in the symmetrical Doherty amplifier circuit according to another embodiment.

8th FIG. 12 illustrates a circuit diagram of a phase shifter included in the symmetrical Doherty amplifier circuit according to another embodiment.

DETAILED DESCRIPTION

1 illustrates an embodiment of a symmetrical Doherty amplifier circuit 100 that have a main amplifier 102 and a top amplifier 104 having. The main amplifier 102 is biased to class B or AB mode, and the peak amplifier 104 is biased to class C mode. The main and the top amplifier 102 . 104 have the same size, ie the main and the top amplifier 102 . 104 are not deliberately different. Alternatively, the peak amplifier 104 slightly smaller or larger than the main amplifier 102 be. In any case, every amplifier is 102 . 104 via an input matching device 106 . 108 with a corresponding input (input no. 1, input no. 2) coupled. The amplifiers 102 . 104 are above respective output equalizers 112 . 114 and an impedance combiner 116 with a load 110 coupled. The impedance combiner 116 is in 1 as a Doherty combiner. In general, however, any type of suitable impedance combiner can be used to drive the amplifiers 102 . 104 with the load 110 connect to. One or both of the output balancing devices 112 . 114 can in the impedance combiner 116 be integrated.

At low power levels, only the main amplifier is 102 in operation. The efficiency of the main amplifier 102 increases with increasing power level. The main amplifier 102 Eventually, it reaches a maximum efficiency point (ie, saturation) as the power level continues to increase. At this power level, the peak amplifier turns on 104 one. The efficiency of the peak amplifier 104 increases equally for power levels above this point and ultimately reaches its maximum efficiency point (ie, saturation). At this point, the symmetrical Doherty amplifier circuit operates 100 at peak output power. That is, the symmetric Doherty amplifier circuit 100 works at peak output when both amplifiers are working 102 . 104 in a saturation state, and at OBO if the main amplifier 102 is in the saturation state and the peak amplifier 104 is not in the saturation state.

The efficiency of the symmetrical Doherty amplifier circuit 100 at an OBO operating point below the peak output depends on that through the main amplifier 102 perceived VSWR. The main amplifier 102 can be done by controlling the phase at the output of the peak amplifier 104 be set to operate at high VSWR. An additional phase at the output of the peak amplifier increases the VSWR that passes through the main amplifier 102 is perceived. The symmetrical Doherty amplifier circuit 100 can with high efficiency with more than 6 dB decrease of the peak output power (ie with more than 6 dB OBO) by corresponding shifting of the phase at the output of the peak amplifier 104 work. The phase at the output of the peak amplifier 104 can be changed dynamically, resulting in a phased load modulation of the main amplifier 102 leads. By dynamically controlling the VSWR and load modulation of the main amplifier 102 in this way, the maximum efficiency operating point of the symmetrical Doherty amplifier circuit 100 be dynamically moved through the output power range at OBO. For example, the maximum efficiency operating point of the symmetrical Doherty amplifier circuit 100 at OBO anywhere between 6 dB and 12 dB OBO or more by appropriately shifting the phase of the peak amplifier 104 lie. For cases where the top amplifier 104 slightly smaller than the main amplifier 102 is that can through the main amplifier 102 perceived load modulation also less than 6 dB OBO cover.

For this purpose, the symmetrical Doherty amplifier circuit 100 Phase shifting circuits 118 on which the output phase of the peak amplifier 104 at OBO so shift that through the main amplifier 102 perceived load impedance and the efficiency of the symmetrical Doherty amplifier circuit 100 both increase at OBO as a function of the phase shift at the peak amplifier output. This allows the main amplifier 102 to work into a higher impedance, ie the main amplifier 102 perceives a higher VSWR, making it more efficient.

2 FIG. 12 illustrates a diagram illustrating the main amplifier efficiency as a function of the peak output power OBO (P3dB) shows different phase shifts at the peak amplifier output. As in 2 can be seen, the phase at the peak amplifier output is shifted by 0 to 65 degrees at OBO. In one embodiment, the phase is at the output of the peak amplifier 104 shifted by 10 to 60 degrees at OBO. Increasing the phase at the peak amplifier output increases that through the main amplifier 102 perceived VSWR, which in turn improves the efficiency of the symmetric Doherty amplifier circuit 100 increased for a given OBO operating point.

The maximum efficiency of the symmetrical Doherty amplifier circuit 100 at OBO, at any OBO operating point between, for example, 6 dB OBO and 12 dB OBO or more by changing the through the main amplifier 102 perceived VSWR, ie by shifting the phase at the output of the peak amplifier 104 to be moved. This is also in 2 which shows that the symmetrical Doherty amplifier circuit 100 reaches a maximum efficiency operating point at 6 dB OBO when the output phase of the peak amplifier 104 is increased by 40 degrees, reaching a maximum efficiency operating point at 7 dB OBO when the output phase of the peak amplifier 104 is increased by 50 degrees, reaching a maximum efficiency operating point at 8 dB OBO when the phase at the output of the peak amplifier 104 increased by 55 degrees, etc.

The load modulation of the main amplifier 102 is determined by the base current ratio between the main amplifier 102 and the top amplifier 104 implemented. In addition, the Doherty combiner combines or summed 116 the load currents of the amplifiers 102 . 104 in a summing node 120 , so that the output voltage of the balanced Doherty amplifier circuit 100 is determined by the summation of the load currents multiplied by the load impedance. For this purpose, the Doherty combiner points 116 a first impedance Z1, which is the output of the main amplifier 102 with the summing node 120 coupled. The output of the peak amplifier 104 is also with the summing node 120 coupled. A second impedance Z2 of the Doherty combiner 116 couples the summing node 120 with the load 110 ,

In some embodiments, the phase shifter circuits may 118 the phase at the output of the peak amplifier 104 dynamically shift to a phase control of the load modulation of the main amplifier 102 make. This in turn allows the main amplifier 102 if necessary working into different impedances (ie the main amplifier 102 can perceive different VSWRs), making it more efficient over a wide output power range.

3 Figure 12 illustrates a diagram showing the main amplifier load modulation (ie, the VSWR) as a function of the phase shift at the peak amplifier output. As shown, the main amplifier load modulation increases as a function of increasing the phase shift at the peak amplifier output. The relationship between the VSWR and the peak amplifier output phase allows the main amplifier 102 to work in higher impedances to increase the efficiency of the symmetrical Doherty amplifier circuit 100 to increase.

4 Fig. 13 is a diagram showing the main amplifier efficiency as a function of the peak output power OBO (P3dB). The curve "A" in 4 corresponds to the main amplifier efficiency as a function of the OBO below the peak output power with phased load modulation, and the curve "B" corresponds to the main amplifier efficiency with fixed load modulation, ie without phase shift at the peak amplifier output. A phased load modulation of the main amplifier 102 can by controlling the output phase of the peak amplifier 104 be realized, as explained above. That through the main amplifier 102 Accordingly, the sensed VSWR increases as a function of the amount of phase shift introduced by the phase shifter circuits 118 at the output of the peak amplifier 104 is made.

In an embodiment, the phase shifter circuits include 118 a first phase shifter 122 which is connected to the input of the main amplifier 102 coupled, and a second phase shifter 124 that with the output of the peak amplifier 104 is coupled. The first phase shifter 122 performs a phase shift at the input of the main amplifier 102 off, and the second phase shifter 124 similarly introduces a phase shift at the output of the peak amplifier 104 out. The phase shifters 122 . 124 can be controlled by a phase control circuit 126 be configured to perform the same phase shift. That is, the first phase shifter 122 may have the same phase shift at the input of the main amplifier 102 run, the second phase shifter 124 at the output of the peak amplifier 104 performs.

5 illustrates another embodiment of the symmetrical Doherty amplifier circuit 100 , In the 5 embodiment shown is similar to in 1 shown embodiment. However, the phase shifter circuits include 118 also a third phase shifter 128 who is in the Doherty combiner 116 between the impedance Z1 and the summing node 120 is integrated. Every phase shifter 122 . 124 . 128 can through the phase control circuit 126 be configured. The phase shifter 124 at the output of the peak amplifier 104 put that through the main amplifier 102 perceived VSWR. The other phase shifters 122 and 128 perform a combined phase shift that is approximately equal (ie, identical or nearly equal) to the phase shift imposed by the phase shifter 124 is performed. The phase shifters 122 . 124 . 128 , which are a part of the phase shifter circuits 118 can form, depending on the application, in which the symmetrical Doherty amplifier circuit 100 is used to provide a fixed phase shift amount or an adjustable phase shift amount.

6 illustrates an embodiment of the phase shifters 122 . 124 . 128 in the phase shifter circuits 118 are included. According to this embodiment, the phase shifters 122 . 124 . 128 a first switch 130 which is coupled to an input impedance Zin, and a second switch 132 which is coupled to an output impedance Zout. Between the switches 130 . 132 There are at least two additional transmission lines with impedances Zadd1, Zadd2 of different lengths. A phase line can be formed by connecting the switches 130 . 132 is set such that one of the intermediate impedances Zadd1, Zadd2 is connected between the input and output impedances Zin, Zout. For example, if both transistors are at peak output power 102 . 104 are in a saturation state, so does the phase control circuit 118 the switches 130 . 132 such that the optimum length intermediate impedance (for example, Zadd1) for the peak output power is connected between the input and output impedances Zin, Zout. At OBO, the output phase of the peak amplifier becomes 104 increased when the phase control circuit 118 the switches 130 . 132 is set so that a longer intermediate impedance (for example, Zadd2) is connected between the input and output impedance Zin, Zout to form a longer phase line. In this way, the length of the phase lines connected to the output of the peak amplifier 104 and the input of the main amplifier 102 be adjusted under OBO conditions. Any suitable number of intermediate impedances of different lengths can be arranged, so that the setting by the switches 130 . 132 can be extended over a broad range of degrees (e.g., 10 to 60 degrees) and the amplifier efficiency can be maximized over a wide range of OBO operating points (eg, 6 dB OBO to 12 dB OBO or more).

7 illustrates another embodiment of the phase shifter 122 . 124 . 128 in the phase shifter circuits 118 are included. According to this embodiment, the phase shifter 122 . 124 . 128 a high pass circuit 134 and a low pass circuit 136 between two switches 138 . 140 on. At peak output power, the phase control circuit 118 the switches 138 . 140 such a thing that the high pass circuit 134 in the amplifier circuit 100 is switched into. The output phase of the peak amplifier 104 is increased at OBO when the phase control circuit 118 the switches 138 . 140 so sets that the low pass circuit 136 in the amplifier circuit 100 is turned on, causing the with the amplifiers 102 . 104 connected phase lines are practically extended.

8th illustrates another embodiment of the phase shifter 122 . 124 . 128 in the phase shifter circuits 118 are included. According to this embodiment, the phase shifters include 122 . 124 . 128 a quadrature phase shifter core 142 and switches 144 . 146 , the different capacitors C1, C2, C3, C4 depending on the power state of the amplifier circuit 100 controllable with the quadrature phase shifter core 142 can connect. For example, more phase shift may be performed during OBO conditions by switching the capacitors C1 / C3 or C2 / C4 with the respective values switchable with the quadrature phase shifter core 142 get connected. Still other phase shift circuits may be used to control the output phase of the peak amplifier 104 to move.

Terms such as "equal," "agree," and "agree" mean identical, nearly identical, or approximate in the meaning of the present text, so that some reasonable amount of deviation is contemplated without departing from the spirit of the invention. The term "constant" means without change or variation, or also with so little variation or variation, that a certain reasonable amount of deviation is taken into consideration without departing from the spirit of the invention. Furthermore, terms such as "first," "second," and the like are used to describe various elements, regions, sections, etc., and are not to be construed in a limiting sense. Like terms refer to like elements throughout the description.

As used herein, the terms "comprising," "containing," "comprising," and the like, are open-ended terms that indicate the presence of specified elements or features, but do not exclude other elements or features. The items "a," "an," "an," and "the" include both singular and plural unless the context clearly requires a different interpretation.

It is understood that the features of the various embodiments described herein may be combined with each other unless expressly stated otherwise.

While specific embodiments have been illustrated and described herein, it will be understood by those skilled in the art that a variety of alternative and / or equivalent implementations may be substituted for the specific embodiments shown and described without departing from the scope of the present invention. It is intended that all adaptations or variations of the embodiments specifically discussed herein fall within this application. Therefore, it is intended that this invention be limited only by the claims and their equivalents.

Claims (15)

Doherty amplifier circuit ( 100 ), comprising: a symmetrical Doherty amplifier comprising a main amplifier ( 102 ) and a peak amplifier ( 104 ) of the same size as the main amplifier ( 102 ), wherein the symmetrical Doherty amplifier is configured to operate at peak output power when the main amplifier ( 102 ) and the peak amplifier ( 104 ) are each in the saturation state, and at output back-off (OBO) to work when the main amplifier ( 102 ) is in the saturation state and the peak amplifier ( 104 ) is not in the saturation state; and phase shifter circuits ( 118 ) configured to phase out an output of the peak amplifier ( 104 ) at OBO so that one through the main amplifier ( 102 ) and the efficiency of the symmetrical Doherty amplifier both at OBO as a function of the phase shift at the output of the peak amplifier (FIG. 104 ) increase. Doherty amplifier circuit ( 100 ) according to claim 1, wherein the phase shifter circuits ( 118 ) a first phase shifter ( 122 ) connected to an input of the main amplifier ( 102 ) and a second phase shifter ( 124 ) connected to the output of the peak amplifier ( 104 ), and wherein the first and second phase shifters are configured to perform the same phase shift. Doherty amplifier circuit ( 100 ) according to claim 2, further comprising a Doherty combiner ( 116 ) configured to connect the main and the peak amplifiers ( 104 ) with a load, the phase shifter circuits ( 118 ) further includes a third phase shifter ( 128 ) included in the Doherty combiner ( 116 ), and wherein the first phase shifter ( 122 ) and the third phase shifter ( 128 ) provide a combined phase shift approximately equal to a phase shift produced by the second phase shifter ( 124 ) provided. Doherty amplifier circuit ( 100 ) according to claim 1, wherein the phase shifter circuits ( 118 ) are configured to phase out the output of the peak amplifier ( 104 ) to shift 10 to 60 degrees at OBO. Doherty amplifier circuit ( 100 ) according to claim 1, wherein the phase shifter circuits ( 118 ) are configured to phase out the output of the peak amplifier ( 104 ) at OBO over a range of degrees sufficient to move a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO to an operating point between at least 6 dB OBO and 12 dB OBO. Doherty amplifier circuit ( 100 ) according to claim 1, wherein the phase shifter circuits ( 118 ) are configured to phase out the output of the peak amplifier ( 104 ) at OBO by extending a phase line connected to the output of the peak amplifier ( 104 ) and extending a phase line connected to an input of the main amplifier ( 102 ) is to move. Doherty amplifier circuit ( 100 ) according to claim 6, wherein the phase shifter circuits ( 118 ) are configured to extend the phase lines by 10 to 60 degrees at OBO. Method for operating a Doherty amplifier circuit ( 100 ), which has a main amplifier ( 102 ) and a peak amplifier ( 104 ) of the same size as the main amplifier ( 102 ), the method comprising: operating the symmetrical Doherty amplifier at peak output power when the main amplifier ( 102 ) and the peak amplifier ( 104 ) are each in the saturation state, and output back-off (OBO) when the main amplifier ( 102 ) is in the saturation state and the peak amplifier ( 104 ) is not in the saturation state; and shifting the phase at an output of the peak amplifier ( 104 ) in OBO so that one through the main amplifier ( 102 ) and the efficiency of the symmetrical Doherty amplifier both in OBO as a function of Phase shift at the output of the peak amplifier ( 104 ) increase. The method of claim 8, wherein shifting the phase at the output of the peak amplifier ( 104 ) in OBO, the application of the same phase shift at the output of the peak amplifier ( 104 ) and at an input of the main amplifier ( 102 ). The method of claim 9, further comprising applying the same phase shift to a phase line of a Doherty combiner comprising the main and the peak amplifiers ( 104 ) coupled with a load. Method according to claim 8, wherein the phase at the output of the peak amplifier ( 104 ) is shifted by 10 to 60 degrees at OBO. Method according to claim 8, wherein the phase at the output of the peak amplifier ( 104 ) at OBO can be shifted over a range of degrees sufficient to move a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO to an operating point between at least 6 dB OBO and 12 dB OBO. The method of claim 8, wherein shifting the phase at the output of the peak amplifier ( 104 ) in OBO comprises: extending a phase line connected to the output of the peak amplifier ( 104 ) connected is; and extending a phase line connected to an input of the main amplifier ( 102 ) connected is. The method of claim 13, wherein the phase lines are extended by 10 to 60 degrees at OBO. Doherty amplifier circuit ( 100 ), comprising: a symmetrical Doherty amplifier comprising a first amplifier of a first size and a second amplifier of a second size equal to the first size, wherein the symmetrical Doherty amplifier is configured to operate at peak output power when the first amplifier and the second amplifier are each in the saturation state and to operate at output back-off (OBO) when the first amplifier is in the saturation state and the second amplifier is not in the saturation state; and circuits configured to dynamically control a voltage standing wave ratio (VSWR) sensed by the first amplifier such that a maximum efficiency operating point of the symmetrical Doherty amplifier at OBO is at an operating point between at least one of 6 dB OBO and 12 dB OBO by changing the VSWR sensed by the first amplifier.

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